Understanding PFAS treatment technologies
PFAS treatment is a growing area of concern for water utilities, businesses and communities, particularly as governments pass stricter regulations. Research increasingly shows the harmful effects of PFAS on humans and ecosystems. Discover how PFAS treatment technologies can provide safer drinking water and limit the amount of PFAS in the environment.
What are PFAS and why are they harmful?
Per- and polyfluoroalkyl substances (PFAS) are a group of man-made chemicals widely used in various industrial and consumer products due to their resistance to water, oil, and heat. These substances have been used in products like non-stick cookware, water-repellent clothing, firefighting foams, and food packaging.
PFAS are highly persistent in the environment and human body, which is why they are often referred to as "forever chemicals." Due to their widespread use and longevity, PFAS have become a significant contaminant in water sources, leading to concerns about their impact on human health, including potential links to cancer, hormone disruption, and immune system effects.
How pervasive are PFAS in the environment?
PFAS are extremely pervasive in the environment due to their widespread use and remarkable persistence. They have been detected in air, soil, and water bodies across the globe, including in remote areas far from any known source of contamination. PFAS have also been found in the blood of humans and wildlife, indicating widespread exposure.
Their resistance to natural degradation processes means that once released into the environment, PFAS can persist for decades, accumulating in ecosystems and moving through the food chain.
This widespread contamination has made PFAS a significant environmental and public health concern, prompting increased efforts to monitor, regulate, and develop technologies for PFAS treatment.
Why do utilities need to prioritize PFAS treatment?
Utilities must prioritize PFAS treatment to protect communities and comply with increasingly strict PFAS regulations for drinking water. In April 2024, the Biden-Harris Administration established the first-ever national, enforceable drinking water standard for PFAS, aiming to reduce exposure for approximately 100 million Americans. Global regulations on PFAS treatment are also tightening. In the European Union, new rules limit PFAS levels in drinking water, with compliance required from Member States by 2026.
Traditional water treatment methods, such as coagulation and chlorination, are ineffective for PFAS treatment. To meet stricter PFAS regulations, water utilities can leverage existing PFAS treatment technologies, such as granular activated carbon, reverse osmosis, and ion exchange systems. Water utilities should begin testing and monitoring for PFAS now, so they can upgrade their infrastructure in time to meet upcoming PFAS limits.
What different types of PFAS are there?
PFAS include a broad range of chemicals, often categorized into two main groups: long-chain and short-chain PFAS.
Long-chain PFAS: Include substances like perfluorooctanoic acid (PFOA) and perfluorooctanesulfonic acid (PFOS), which have been widely used in industrial applications and consumer products.
Short-chain PFAS: Include substances such as perfluorobutanesulfonic acid (PFBS) and perfluorobutanoic acid (PFBA). Developed as alternatives to long-chain PFAS, these substances still pose environmental and health concerns despite their lower accumulation in organisms.
PFAS treatment technologies for drinking water
PFAS treatment technologies for drinking water primarily include activated carbon filtration, ion exchange, advanced liquid phase adsorption systems, and reverse osmosis:
Activated carbon filtration: This PFAS treatment method, particularly using granular activated carbon (GAC), is widely used due to its ability to adsorb PFAS from water, effectively capturing these compounds on the surface of the carbon material.
Ion exchange resins: In this common PFAS treatment technology, the resins exchange harmful PFAS ions in the water with harmless ones, reducing PFAS concentration.
Advanced liquid phase adsorption systems: These systems for PFAS treatment may use a variety of specialized adsorbents, including ion exchange resins, synthetic polymers, or specially engineered carbons, tailored to target specific contaminants.
Reverse osmosis: This PFAS treatment method, involving a high-pressure membrane filtration process, is highly effective in removing PFAS by filtering water through a semipermeable membrane that blocks PFAS molecules and allowing clean water to pass through.
PFAS treatment recommendations for water utilities
Assess water sources and PFAS types: Water utilities looking to implement effective PFAS treatment strategies should begin by thoroughly assessing their water sources to identify the presence and concentration of PFAS compounds. This includes conducting detailed water quality testing to determine the specific types of PFAS present and their levels relative to regulatory standards.
Selecting the optimal PFAS treatment technology: Once the contamination is understood, utilities should explore proven PFAS treatment technologies such as granular activated carbon (GAC) filtration, ion exchange resins, or advanced liquid phase adsorption systems.
It’s crucial to select the technology best suited to the local water chemistry and treatment goals, possibly starting with a pilot test to confirm the effectiveness of the chosen method.
Regular monitoring and maintenance: In addition to selecting the appropriate PFAS treatment technology, utilities should develop a comprehensive plan that includes regular monitoring and maintenance to ensure ongoing compliance with current regulations. This plan should also account for potential changes in PFAS regulations, which are becoming increasingly stringent.
Choose the right partner for PFAS treatment: Collaborating with experienced partners like Xylem can provide utilities with access to the latest PFAS treatment technologies and expert guidance on system design, implementation, and long-term operation. By taking these steps, water utilities can effectively protect their communities and customers from PFAS contamination while ensuring compliance with evolving regulatory requirements.
Xylem’s proven technologies for PFAS treatment
Xylem offers a diverse range of PFAS treatment solutions tailored to various industries, including municipal drinking water systems, industrial wastewater treatment, and construction dewatering.
Municipalities: Xylem provides technologies like granular activated carbon (GAC) filtration, ion exchange resins, and advanced liquid phase media adsorption systems to ensure that communities receive safe, clean water that meets regulatory standards. These solutions are available as both permanent installations and emergency PFAS treatment mobile units, making them adaptable to different water chemistries and urgent needs.
Industrial and commercial settings: Xylem’s PFAS treatment technologies are crucial for treating wastewater and contaminated groundwater. Our mobile filtration systems are particularly effective for construction projects, quickly reducing PFAS levels to non-detectable levels, ensuring compliance, and allowing safe water discharge.
Specialized solutions: Xylem offers specialized PFAS treatment solutions for airports and military bases, addressing PFAS contamination from firefighting foams through both groundwater and soil remediation. Our technology-agnostic approach ensures that the most effective PFAS treatment methods are selected for each specific application.
Four successful PFAS treatment projects
1. Colorado water utility addresses PFAS treatment with ion exchange system
The Stratmoor Hills Water & Sanitation District (SHWSD) near Colorado Springs identified PFOA and PFOS contamination in one of its seasonal wells, prompting the need for effective PFAS treatment.
Xylem provided a PFAS treatment solution using selective single-use ion exchange resin, which efficiently targeted and removed PFAS compounds from the water. The ion exchange system successfully reduced PFAS levels to below detection limits, far exceeding EPA standards. The success of this system led to the expansion of their PFAS treatment efforts with a permanent facility capable of treating up to 1.1 million gallons of water per day.
2. Maine water utility uses granular activated carbon for PFAS treatment
The Kennebunk, Kennebunkport & Wells Water District (KKWWD) in Maine faced PFAS contamination in one of its supply wells and required a reliable PFAS treatment solution.
Xylem implemented a granular activated carbon (GAC) system, specifically utilizing coconut-based carbon, which provides extended bed life and lower life cycle costs compared to alternatives. The GAC filtration method effectively adsorbed the PFAS contaminants, ensuring the water met safety standards. To date, the system has treated over 200 million gallons of water, maintaining non-detect levels of PFAS.
3. Mobile filtration system provides PFAS treatment for construction project
During the construction of a new convention center in Muskegon, Michigan, PFAS was detected in the groundwater being pumped from the building site, necessitating immediate PFAS treatment.
Xylem provided a mobile carbon filtration system that quickly addressed the issue by utilizing activated carbon to filter out the PFAS contaminants. The mobile solution treated 21 million gallons of water, effectively reducing PFAS levels to non-detect levels throughout the project.
4. California water utility deploys 30 systems for large-scale PFAS treatment
The Orange County Water District (OCWD) in California faced significant PFAS contamination in its drinking water wells, potentially affecting millions of customers and requiring an extensive PFAS treatment effort.
Xylem installed 30 multi-use vessel systems, which employed advanced liquid phase media adsorption to treat the contaminated water. This large-scale filtration approach was part of the largest PFAS treatment pilot in the US, with the capacity to treat up to 86 million gallons of water per day.
Explore Xylem’s proven solutions for PFAS treatment.